Optimal design of experiments
Material type: TextSeries: Classics in applied mathematics, 50Publication details: Philadelphia : SIAM/Society for Industrial and Applied Mathematics, ©2006.Description: xxix, 454 pages : illustrationsISBN:- 9780898716047
- 0898716047
- 519.5 PUK
Item type | Current library | Collection | Call number | Status | Date due | Barcode | Item holds | |
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Lending Books | Main Library Stacks | Reference | 519.5 PUK (Browse shelf(Opens below)) | Available | 012089 | |||
Reference Books | Main Library Reference | Reference | 519.5 PUK (Browse shelf(Opens below)) | Available | 011284 |
Browsing Main Library shelves, Shelving location: Stacks, Collection: Reference Close shelf browser (Hides shelf browser)
519.5 NAG Basic Statistics | 519.5 PIL Practical Statistics | 519.5 PIL Statistics: Theory and Practice | 519.5 PUK Optimal design of experiments | 519.5 RAM A Concise Book on Statistics | 519.5 RIC Mathematical statistics and data analysis | 519.5 ROS Introduction to probability and statistics for engineers and scientists / |
Bibliography & Index
Experimental designs in linear models --
Optimal designs for scalar parameter systems --
Information matrices --
Loewner optimality --
Real optimality criteria --
Matrix means --
The general equivalence theorem --
Optimal moment matrices and optimal designs --
D-, A-, E-, T-optimality --
Admissibility of moment and information matrices --
Bayes designs and discrimination designs --
Efficient designs for finite sample sizes --
Invariant design problems --
Kiefer optimality --
Rotatibility and response surface designs.
Optimal Design of Experiments offers a rare blend of linear algebra, convex analysis, and statistics. The optimal design for statistical experiments is first formulated as a concave matrix optimization problem. Using tools from convex analysis, the problem is solved generally for a wide class of optimality criteria such as D-, A-, or E-optimality. The book then offers a complementary approach that calls for the study of the symmetry properties of the design problem, exploiting such notions as matrix majorization and the Kiefer matrix ordering. The results are illustrated with optimal designs for polynomial fit models, Bayes designs, balanced incomplete block designs, exchangeable designs on the cube, rotatable designs on the sphere, and many other examples.
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